In-depth evaluation of saliency maps for interpreting convolutional neural network decisions in the diagnosis of glaucoma based on fundus imaging
Date
2023Abstract
Glaucoma, a leading cause of blindness, damages the optic nerve, making early diagnosis
challenging due to no initial symptoms. Fundus eye images taken with a non-mydriatic retinograph
help diagnose glaucoma by revealing structural changes, including the optic disc and cup. This
research aims to thoroughly analyze saliency maps in interpreting convolutional neural network
decisions for diagnosing glaucoma from fundus images. These maps highlight the most influential
image regions guiding the network’s decisions. Various network architectures were trained and
tested on 739 optic nerve head images, with nine saliency methods used. Some other popular
datasets were also used for further validation. The results reveal disparities among saliency maps,
with some consensus between the folds corresponding to the same architecture. Concerning the
significance of optic disc sectors, there is generally a lack of agreement with standard medical criteria.
The background, nasal, and temporal sectors emerge as particularly influential for neural network
decisions, showing a likelihood of being the most relevant ranging from 14.55% to 28.16% on average
across all evaluated datasets. We can conclude that saliency maps are usually difficult to interpret
and even the areas indicated as the most relevant can be very unintuitive. Therefore, its usefulness
as an explanatory tool may be compromised, at least in problems such as the one addressed in
this study, where the features defining the model prediction are generally not consistently reflected
in relevant regions of the saliency maps, and they even cannot always be related to those used as
medical standards.